Optical recording and reproducing apparatus for tracking wobbling guide grooves

ABSTRACT

An optical recording and reproducing apparatus uses a laser to form one or more spots on an information recording medium preformatted with wobbling guide grooves, and detects tracking error. If the differential push-pull method of detecting tracking error is used, a center spot is flanked by satellite spots distant by an odd multiple of half the repeating period of tile wobble. If the three-beam method is used, the distance is an odd multiple of one-fourth the repeating period of the wobble. If the push-pull method is used, a split photodetector generates a pair of electrical signals. The sum and difference of these signals are filtered, then synchronously detected, and the result is combined with the difference signal to generate a corrected tracking error signal.

This application is a divisional of copending application Ser. No. 08/196,463, filed on Feb. 15, 1994, now U.S. Pat. No. 5,383,169; which was a divisional of application Ser. No. 07/935,925 filed on Aug. 27, 1992, now U.S. Pat. No. 5,303,216.

BACKGROUND OF THE INVENTION

This invention relates to optical recording and reproducing apparatus employing media preformatted with wobbling guide grooves, more particularly to the detection of tracking error in such apparatus.

Optical reproducing apparatus is already widely manufactured and sold in the form of compact disc players, and apparatuses are now becoming available that can both reproduce and record information, using write-once-read-many media or overwritable media. In both types of apparatuses information is read from (or written on) spiral or concentric tracks by means of a laser beam. The beam is kept on-track by a system that detects tracking error, and a servo system that corrects the detected tracking error.

A variety of methods are used to detect tracking error. In the well-known push-pull method, the laser beam is reflected from the medium to a split photodetector. Signals from the two halves of the detector are added to obtain the reproduced information signal, and mutually subtracted to obtain a tracking error signal.

In another method known as the three-beam, triple-beam, tri-beam, or twin-spot method, three laser beams are focused onto the medium, creating three spots that are aligned at an angle to the tracks. The center spot is used for reading or writing information. The other two spots, referred to as satellite spots, are reflected to two separate photodetectors, and the difference between the photodetector output signals is used as the tracking error signal.

Still another method, known as the differential push-pull method, also employs three spots, but reflects each spot to a split photodetector that generates a difference signal. The tracking error signal is obtained by adding the two difference signals from the satellite spots and subtracting the difference signal from the center spot.

These three methods were originally developed for use with media having regular circular or spiral tracks, but there has been a recent movement toward media on which time tracks are formed in wobbling guide grooves. For example, standards for compact disc (CD) media have been proposed in which absolute address information and information for constant linear velocity control are encoded in time wobble.

A general problem arising with such media is that if the tracking error detection system detects the wobble, the tracking servo may attempt to track the wobble, thereby defeating the purpose of time wobble. In the push-pull method, for example, if the servo system tracks the wobble accurately, the information encoded in the wobble is lost. A similar problem occurs in the differential push-pull method when the spacing between the three spots is one-fourth the repeating period of the wobble.

A somewhat different problem can occur in the three-beam method. If the two satellite spots are separated by a distance equal to the repeating period of the wobble, the servo system tracks the wobble at the locations of the satellite spots, thereby doubling the amplitude of the wobble at the central read/write spot. In recording, this leads to poorly formed pits; in reproducing, it degrades the quality of the reproduced signal.

The wobble-tracking problem is related to the problem of tracking offset, which can be caused by tilting of the rotating medium or track-following movement of the objective lens. This problem occurs particularly when the push-pull method is used. Previous attempts to correct offset by means of sensors that detect media tilt and objective-lens movement have been unsatisfactory, in part because they increase the complexity and cost of the apparatus. Attempts to avoid the second type of offset by moving the optical system as a whole instead of just the objective lens also increase the cost of the apparatus, because a more powerful actuator is needed.

SUMMARY OF THE INVENTION

It is accordingly an object of the present invention to generate a tracking error signal with reduced wobble and offset components.

Another object of the invention is to reduce the cost of optical recording and reproducing apparatus.

According to one aspect of the invention, all optical recording and reproducing apparatus record or reproduce information on or from information recording media having guide grooves that wobble with a certain repeating period. The apparatus comprises a laser for emitting one or more laser beams and an optical system for focusing the beam or beams to form a center spot and two satellite spots on the information-recording medium. The center spot and satellite spots are aligned in a straight line at all angle to the guide grooves. The center spot is disposed midway between the satellite spots and is distant from each satellite spot by an odd multiple of substantially one-half the repeating period of the wobble. Tracking error is detected by the differential push-pull method.

According to another aspect of the invention, the center spot is distant from each satellite spot by an odd multiple of substantially one-fourth the repeating period of the wobble and tracking error is detected by the three-beam method.

According to still another aspect of the invention, the optical system forms a single spot on the information-recording medium, and a difference signal is generated by the push-pull method. A bandpass filter extracts the wobble component of this difference signal. The wobble component and the reproduced information signal are input to a synchronous detector that produces a correction signal. A correction circuit combines the correction signal with the difference signal to produce a tracking error signal.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a sectional view of the optical system and related parts of a novel optical recording and reproducing apparatus employing the differential push-pull method.

FIG. 2 is a plan view of the information recording medium in FIG. 1, showing the positions of the spots.

FIG. 3 is a schematic diagram of the tracking error detection circuit of the apparatus in FIG. 1.

FIG. 4 is a simplified sectional view of the optical system, illustrating offset caused by tilt of the information recording medium.

FIG. 5 is another simplified sectional view of the optical system, illustrating offset caused by movement of the objective lens.

FIG. 6 is another plan view of the information recording medium.

FIG. 7 is a sectional view of the optical system and related parts of a novel optical recording and reproducing apparatus employing the three-beam method.

FIG. 8 is a plan view of the information recording medium in FIG. 7, showing the positions of the spots.

FIG. 9 is a schematic diagram of the tracking error detection circuit of the apparatus in FIG. 7.

FIG. 10 is a sectional view of the optical system and related parts of another novel optical recording and reproducing apparatus employing the three-beam method.

FIG. 11 is a sectional view of the optical system and a schematic diagram of the tracking error detection circuit of a novel optical recording and reproducing apparatus employing the push-pull method.

FIG. 12 is a plan view of the information recording medium in FIG. 11.

FIG. 13 is a schematic diagram Illustrating a variation of the synchronous detector in FIG. 11.

DETAILED DESCRIPTION OF THE INVENTION

Novel optical recording and reproducing apparatus employing the differential push-pull method, the three-beam method, and the push-pull method of tracking error detection will be described with reference to the attached drawings. The drawings are illustrative and do not restrict the scope of the invention, which should be determined solely from the appended claims.

Referring to FIG. 1, a first novel optical recording and reproducing apparatus comprises a disc-shaped information recording medium 2 that rotates in a plane at right angles to the page, and a semiconductor laser 4 that emits a laser beam 5. An optical system 6 diffracts and focuses the laser beam 5 to form a center spot 8 and two satellite spots 10 and 12 on the information recording medium 2. Three split photodetectors 14, 16, and 18 receive light reflected from the information recording medium 2 and convert the light to electrical signals that are input to a tracking error detection circuit to be shown later.

The optical system 6 comprises a collimator lens 20, a diffraction grating 22, a polarizing beam splitter 24, a quarter-wave plate 26, an objective lens 28, and a convergent lens 30. The collimator lens 20 converts the divergent laser beam 5 emitted by the laser 4 to a parallel beam. The diffraction grating 22 separates this parallel beam into three beams: a zeroth-order diffracted beam 32, and two first-order diffracted beams 34 and 36. These three beams pass through the polarizing beam splitter 24 and the quarter-wave plate 26 and are focused by the objective lens 28 onto the information recording medium 2, the zeroth-order diffracted beam 32 forming the center spot 8 and the first-order diffracted beams 34 and 36 forming the two satellite spots 10 and 12.

After reflection from the information recording medium 2, the three beams 32, 34, and 36 re-enter the optical system 6, pass through the objective lens 28 and the quarter-wave plate 26, are reflected in the polarizing beam splitter 24, and are directed by the convergent lens 30 onto the three split photodetectors 14, 16, and 18. The zeroth-order diffracted beam 32 is received by the first split photodetector 14, while the two first-order diffracted beams 34 and 36 are received by the second and third split photodetectors 16 and 18.

FIG. 2 is a plan view showing part of the information recording medium 2. When the information recording medium 2 is manufactured, it is preformatted with guide grooves 38 that wobble with a substantially constant repeating period W around center lines 40. The wobbling is substantially in phase between adjacent grooves. The center lines 40 are drawn as double lines representing where the edges of the guide grooves 38 would be if the guide grooves did not wobble. The wobble is greatly exaggerated for clarity in the drawings; the actual amplitude of the wobble is nominally one twenty-fifth of the spacing P of the guide grooves 38. This spacing P will be referred to below as the track pitch.

Information is recorded in the guide grooves 38 in the form of pits 41. The areas between the guide grooves 38 are referred to as land areas 42. As shown in the diagram, the spatial frequency of the pits 41 is much higher than the spatial frequency of the wobble. The pits 41 need not follow the wobble of the guide grooves 38; normally they follow the center lines 40 as shown in the drawing. Due to the exaggerated wobble in the drawings, some pits are shown as departing from the guide grooves, but in practice, such departure would be either nonexistent or extremely slight.

The center spot 8 and the two satellite spots 10 and 12 are aligned in a straight line at an angle to the guide grooves 38 (more precisely, at an angle to their center lines 40). The center spot 8 is disposed midway between the two satellite spots 10 and 12, at a distance L from each satellite spot in the horizontal direction in the drawing, i.e., the longitudinal direction of the guide grooves. L is equal to an odd multiple of half the repeating period W. In the drawing L is equal to one-half W, but the invention can be practiced with other odd multiples such as three-halves W, five-halves W, and so on.

L is the distance between the spots in the direction of the guide grooves 38 (the horizontal direction in the drawing). The two satellite spots 10 and 12 are also displaced from the center spot 8 in the vertical direction in the drawing, i.e., in the lateral direction of the guide grooves, by a distance Q equal to one-half the track pitch P. Q is much smaller than L, so the true distance of the center spot 8 from the satellite spots 10 and 12 is substantially equal to L.

FIG. 3 is a schematic diagram illustrating the three photodetectors 14, 16, and 18 and the tracking error detection circuit 43 to which they are connected. As shown, each split photodetector comprises two separate light-receiving surfaces that generate two separate electrical signals.

The tracking error detection circuit 43 comprises four differential amplifiers 44, 46, 48, and 50, a summing amplifier 52, and two variable-gain amplifiers 54 and 56. The differential amplifier 44 receives the two electrical signals D₁ and D₂ output by the first split photodetector 14 and generates a first difference signal E₀. The differential amplifier 46 receives the two electrical signals D₃ and D₄ output by the second split photodetector 16 and generates a second difference signal E₁. The differential amplifier 48 receives the two electrical signals D₅ and D₆ output by the third split photodetector 18 and generates a third difference signal E₂, which is amplified by the variable-gain amplifier 54. The summing amplifier 52 adds the amplified third difference signal E₂ to the second difference signal E₁. The variable-gain amplifier 56 amplifies the resulting sum E₃. The differential amplifier 50 subtracts the amplified sum E₃ from the first difference signal E₀ to generate a tracking error signal TE.

The tracking error signal TE is supplied to a tracking servo system, not shown in the drawings, that positions the three spots 8, 10, and 12 by moving the objective lens 28 in FIG. 1, or by moving the entire optical system 6 together with the laser 4 and the split photodetectors 14, 16, and 18. The tracking servo system is adapted to adjust the positions of the spots 8, 10, and 12 so as to reduce the value of the tracking error signal TE to zero.

The tracking error detection circuit 43 also supplies a constant linear velocity control signal CLV to a spindle servo system, not shown in the drawings, that controls the rotation of the information recording medium 2. The first difference signal E₀ can be used as this constant linear velocity control signal CLV, as shown in the drawing.

Another summing amplifier 57 receives the two electrical signals D₁ and D₂ output from the first split photodetector 32 and generates their sum as a reproduced information signal RF. This signal RF is supplied to signal-processing circuits, not shown in the drawings, that reproduce the information encoded in the pits 41.

Next the difference signals E₀, E₁, and E₂ will be described in more detail.

The three difference signals E₀, E₁, and E₂ have four components: a high-frequency information component due to the pits 41; a lower-frequency wobble component due to the wobble of guide grooves 38; a still lower-frequency tracking error component due to displacement of the center spot 8 from the center line 40 of the guide groove 38 being followed; and an offset component generated by such factors as tilt of the information recording medium 2 and movement of the objective lens 28.

FIG. 4 illustrates how tilt of the information recording medium 2 can generate offset. For clarity, the diffraction grating 22 and the quarter-wave plate 26 are omitted and only the zeroth-order diffracted beam 32 is shown. The center spot 8 is exactly centered in a guide groove 38. If the information recording medium 2 were not tilted, reflected light from the center spot 8 would follow the dashed arrows and illuminate the two halves of the photodetector 14 equally. Because of the tilt, however, the reflected light follows the solid lines and illuminates the two halves of the photodetector 14 unequally, causing a dc offset in the difference signal.

FIG. 5 illustrates how displacement of the objective lens 28 can generate offset. This problem occurs when track following is performed by moving the objective lens 28 without moving the photodetectors. If the objective lens 28 is centered over the guide groove 38 being tracked, as indicated by dashed lines, reflected light follows the dashed arrows and Illuminates the two halves of the photodetector 14 equally. If the objective lens 28 has been moved downward in the drawing, however, as indicated by solid lines, reflected light illuminates the two halves of the photodetector 14 unequally. The resulting offset in the difference signal changes with movement of the objective lens 28, but the change becomes appreciable only after the objective lens 28 has moved much farther than the track pitch P. Over reasonable periods of time, such as during the following of a single track in FIG. 2, this offset can also be treated as a dc component of the difference signal.

Next the use of the constant linear velocity control signal CLV will be described.

The spindle servo system has a bandpass filter that rejects the dc offset component, the low-frequency tracking error component, and the high-frequency information component of the constant linear velocity control signal CLV. The spindle servo thus responds only to the wobble component. The spindle servo is adapted to control the rotation of the information recording medium 2 so that the wobble component has a constant center frequency of, for example, 22.05 kilohertz as in the proposed compact-disc standard.

Although the repeating period W of the wobble is substantially constant, it is not exactly constant; it is modulated slightly to encode absolute address information. This modulation is detected as a frequency modulation of the constant linear velocity control signal CLV with a maximum deviation of ±1 kilohertz. Thus during normal operation the wobble has a frequency of 22.05±1 kilohertz.

Next the tracking error signal TE will be described. The tracking servo system has a low-pass filter that rejects the high-frequency information component of the tracking error signal TE, so the high-frequency information components of the difference signals E₀, E₁, and E₂ will be ignored in this description.

Taken together, the tracking error and wobble components can be approximated by a sine function of the deviation of the spot from the guide groove. Referring to FIG. 6 (in which the pits 41 are omitted for clarity), let U be the deviation of the guide grooves 38 from the center line 40 at the location of the center spot 8. Since the satellite spots 10 and 12 are separated from the center spot 8 by a distance L equal to half the repeating period W of the wobble, at the satellite spots 10 and 12 the guide grooves 38 deviate by an equal amount -U in the opposite direction. Let X be the tracking error, i.e. the deviation of the center spot 8 from the center line 40 (in the drawings X is zero). Then the three difference signals can be represented as follows:

    E.sub.0 =A.sub.0 sin[2π(X-U)/P]+B.sub.0

    E.sub.1 =A.sub.1 sin[2π(X+Q+U)/P]+B.sub.1

    E.sub.2 =A.sub.2 sin[2π(X-Q+U)/P]+B.sub.2

The constants A₀, A₁, and A₂ are the amplitudes of the tracking error plus wobble components of the three difference signals and B₀, B₁, and B₂ are their offset components. Since Q=P/2 and hence 2π Q/P=π, the formulas for E₁ and E₂ can be simplified as follows.

    E.sub.1 =-A.sub.1 sin[2π(X+U)/P]+B.sub.1

    E.sub.2 =-A.sub.2 sin[2π(X+U)/P]+B.sub.2

From FIGS. 4 and 5 it can be understood that offset affects all three difference signals in the same way; that is, the amplitudes and offsets are related as follows:

    A.sub.0 /B.sub.0 =A.sub.1 /B.sub.1 =A.sub.2 /B.sub.2

The gain G₁ of the variable-gain amplifier 54 is set to A₁ /A₂. The signal E₃ can therefore be expressed as follows:

    E.sub.3 =E.sub.1 +G.sub.1 E.sub.2 =-2A.sub.1 sin[2π(X+U)/P]+2B.sub.1

The gain G₂ of the variable-gain amplifier 56 is set to A₀ /(2A₁). The tracking error signal TE is therefore: ##EQU1## Since the wobble U is much smaller than the track pitch P, cos(2π U/P) is substantially equal to unity. To a close approximation, TE is therefore expressible as follows:

    TE=2A.sub.0 sin(2πX/P)

As a sine function of X, this tracking error signal TE accurately represents the tracking error, without offset or wobble. The tracking servo therefore tracks the center line 40 accurately, resulting in a high-quality constant linear velocity control signal CLV, a high-quality reproduced information signal RF during reproduction, and well-formed pits during recording.

In the case of a compact disc with a constant linear velocity between 1.2 and 1.4 meters per second in which the wobble frequency is 22.05±1 kilohertz, to be equal to half the repeating period of the wobble, the separation L between the center spot 8 and the satellite spots 10 and 12 should be 24 to 35 microns. The invention is not restricted to this particular range of values however, odd multiples of half the repeating period of the wobble also being usable.

FIG. 7 shows a second novel optical recording and reproducing apparatus that uses the three-beam method. The optical system is the same as before except that the collimator lens 20 is disposed below the polarizing beam splitter 24, a divergent lens 58 is used instead of the convergent lens 30 in FIG. 1, and an additional cylindrical lens 60 is provided. The zeroth-order diffracted beam 32 reflected from the center spot 8 is received by a quadrant photodetector 62, which provides signals for information reproduction and focus control. The two first-order diffracted beams 34 and 36 reflected from the satellite spots 10 and 12 are received by a first photodetector 64 and a second photodetector 66.

FIG. 8 is a plan view of part of the information recording medium 2, showing the three spots in two positions: one (in the upper part of the drawing) in which the center spot 8 is disposed at a point of minimum wobble, and another (in the lower part of the drawing) in which the center spot 8 is disposed at a point of maximum wobble. Of course the three spots 8, 10, and 12 are in only one position at a time. The lower position results from the upper after a rotation of the information recording medium 2 in the direction of the arrow X.

The distance of the two satellite spots 10 and 12 from the center spot 8 is exactly half what it was in FIG. 2. The displacement Q' in the vertical direction is one-fourth the track pitch P. The separation L' in the horizontal direction in the drawing is one-fourth the repeating period W of the wobble. In the case of media rotating with a constant linear velocity of 1.2 to 1.4 meters per second and a wobble frequency of 22.05±1 kilohertz, the separation L' should be 11 to 18 microns.

FIG. 9 shows the tracking error detection circuit 67 to which the first and second photodetectors 64 and 66 are connected. The first photodetector 64 produces a first electrical signal E₄ that is fed to the non-inverting input of a differential amplifier 68. The second photodetector 66 produces a second electrical signal E₄ that is amplified by a variable-gain amplifier 70 and fed to the inverting input of the differential amplifier 68. The output of the differential amplifier 68 is a tracking error signal TE'.

To avoid obscuring the invention with unnecessary detail, the electronics for processing signals from the quadrant photodetector 62 and generating the reproduced information signal and constant linear velocity control signal are omitted.

The first and second electrical signals E₄ and E₅ can be approximated by cosine functions, with amplitudes A₄ and A₅, of the displacement of the spot from the guide groove, plus offset components B₄ and B₅. Since the satellite spots 10 and 12 are mutually separated by half the repeating period of the wobble, the wobble U' at the satellite spot 12 is equal and opposite to the wobble -U' at the satellite spot 10.

    E.sub.4 =A.sub.4 cos[2π(X-Q'+U')/P]+B.sub.4

    E.sub.5 =A.sub.5 cos[2π(X+Q'-U')/P]+B.sub.5

The gain G₃ of the variable-gain amplifier 70 is set to the amplitude ratio A₄ /A₅, which equals the offset ratio B₄ /B₅. The tracking error signal TE' is accordingly: ##EQU2## Q' is P/4, and U' is much smaller than P, so 2π(Q'-U')/P is close to π/2 and sin[2π(Q'-U')/P] is substantially equal to unity. Therefore to a close approximation:

    TE'=2A.sub.4 sin(2πX/P)

This tracking error signal TE' is free of offset and substantially free of wobble, resulting in the same benefits as in the first novel apparatus: accurate tracking of the center line 40, a high-quality constant linear velocity control signal, a high-quality reproduced information signal during reproduction, and well-formed pits during recording.

It is not necessary for the spacing between the spots to be one-fourth the repeating period W of the wobble as in FIG. 8. A spacing of three-fourths W (33 to 54 microns for media rotating with a constant linear velocity of 1.2 to 1.4 meters per second and a wobble frequency of 22.05±1 kilohertz) gives the same effect, as do other odd multiples of one-fourth W.

The apparatus in FIGS. 1 and 7 uses a diffraction grating to produce three laser beams, but the invention is not restricted to this means of beam production. Instead of a diffraction grating, it is possible to employ a monolithic semiconductor laser array that emits three laser beams from a single lasing region, or a hybrid semiconductor laser array having three lasing regions, each of which emits a single laser beam.

FIG. 10 shows an apparatus that employs a laser array 71 of this type to emit three laser beams 32, 34, and 36. Other components are the same as In FIG. 7, so a description will be omitted. If the beams are disposed so that the interval between the three spots 8, 10, and 12 is an odd multiple of one-fourth the repeating period of the wobble, the same effect is obtained as In FIG. 7. In addition, the cost of the apparatus is reduced because no diffraction grating is needed in the optical system.

A similar type of laser array 71 can be used when the differential push-pull method is employed. In this case the beams should of course be disposed so that the intervals between the spots are an odd multiple of one-half the repeating period of the wobble.

FIG. 11 shows a novel optical recording and reproducing apparatus that uses the push-pull method. As before, the information recording medium 2 has wobbling guide grooves 38 and is controlled to rotate with a constant linear velocity at which the wobble frequency is, for example, 22.05±1 kilohertz.

This method employs only a single laser beam 5 and spot 72, so the optical system requires no diffraction grating or other means of producing multiple beams and spots. FIG. 11 illustrates a simplified representation of the optical system, showing only the collimator lens 20, the polarizing beam splitter 24, and the objective lens 28.

The push-pull method employs a single split photodetector 74 that receives reflected light from the spot 72 and generates a pair of electrical signals D₇ and D₈. These electrical signals D₇ and D₈ are fed to a differential amplifier 76 and a summing amplifier 78. The summing amplifier 78 generates a sum signal that can be used as the reproduced information signal RF. The differential amplifier 76 generates a difference signal E₆ that can be used as the constant linear velocity control signal CLV.

The difference signal E₆ is fed to a bandpass filter 80 with cutoff frequencies of, for example, 20 and 30 kilohertz that extracts the wobble component D of the difference signal E₆. This wobble component D and the sum signal from the summing amplifier 78 are fed to a synchronous detector 81 comprising a low-pass filter 82, an amplifier 84, a multiplier 86, and another low-pass filter 88.

The low-pass filter 82 receives the sum signal RF and rejects its high-frequency information component. The cutoff frequency of the low-pass filter 82 is, for example, 30 kilohertz. The amplifier 84 amplifies the output of the low-pass filter 82 and sends the filtered, amplified sum signal S to the multiplier 86. The multiplier 86 also receives the wobble component D of the difference signal E₆ from the bandpass filter 80. The multiplier 86 multiplies D by S and sends their product M₀ to the low-pass filter 88.

The low-pass filter 88 has a cutoff frequency less than the wobble frequency. If the wobble frequency is 22.05±1 kilohertz, the cutoff frequency of the low-pass filter 88 is, for example, less than 20 kilohertz. The output from the low-pass filter 88 is a correction signal M₁ that is combined with the difference signal E₆ in a correction circuit 89 to generate a corrected tracking error signal CTE.

The correction circuit 89 comprises an amplifier 90 that amplifies the correction signal M₁, and a differential amplifier 92 that subtracts the amplified correction signal received from the amplifier 76 from the difference signal E₆ to generate the corrected tracking error signal CTE.

FIG. 12 is a plan view of part of the information recording medium 2, showing the spot 72 disposed on the center line 40 of a guide groove 38 so that the tracking error X is zero. As before P is the track pitch. The letter V represents the maximum amplitude of the wobble, which is exaggerated in the drawing but is substantially one twenty-fifth of the track pitch P.

Tracking error detection by this optical recording and reproducing apparatus can be described mathematically as follows.

The difference signal E₆ output from the differential amplifier 76 has the same form as the signal E₀ discussed earlier:

    E.sub.6 =Asin[2π(X-U)/P]+B

where A is the amplitude of the tracking error component, B is an offset component, U is the wobble, and X is the tracking error. The wobble U can be expressed as follows:

    U=Vsin(2πft)

where f is the frequency of the wobble (22.05±1 kilohertz, for example) and t represents time.

The bandpass filter 80 rejects frequency components other than the wobble-frequency component. Furthermore, U is much smaller than P, so sin(2πU/P) is substantially equal to U/P. The signal D output by the bandpass filter 80 therefore has the form: ##EQU3##

The low-pass filter 82 eliminates the high-frequency information component of the reproduced information signal RF, so the signal S output by the amplifier 84 has the form:

S=A'cos[2π(X-U)/P]+B'

where A' is the amplitude of the tracking error component and B' is an offset component. The product M₀ of D and S can be calculated as follows: ##EQU4## Since the cutoff frequency of the low-pass filter 22 is less than the wobble frequency f, low-pass filtering of M₀ eliminates DB' and DA'cos(2πX/P) and produces the following correction signal M₁ :

    M.sub.1 =Ksin(2πX/P)

where

    K=-(2πV/P)(2πV/P)AA'/2

K is a constant, so the correction signal M₁ is expressed as a sine function of the tracking error X. The correction signal M₁ itself could therefore be used as a tracking error signal, but it would not be very accurate because of the small value of the constant K.

However, when E₆ is equal to zero, the correction signal M₁ gives an approximate indication of the size of the offset component B. If the gain G₄ of the amplifier 76 is adjusted so that G₄ M₁ =B in this case, the unwanted offset component can be removed from the corrected tracking error signal CTE generated by the differential amplifier 78 when E₆ is zero, thereby causing the tracking servo to move the spot 72 closer to the center line 40. The correction signal M₁ is furthermore wobble-free, so combining M₁ and E₆ in this way reduces the relative magnitude of the unwanted wobble component in CTE. Use of the corrected tracking error signal CTE thus improves both the accuracy and reliability of track following operations.

While the corrected tracking error signal CTE in FIG. 11 is not necessarily as accurate as the tracking error signals TE and TE' generated by the novel apparatus in FIGS. 1 to 10, the apparatus in FIG. 11 has the advantage of lower cost due to a simpler optical system. Moreover, all of the apparatus shown in FIGS. 1 to 12 has the advantage that by eliminating or reducing the offset component of the tracking error signal, it eliminates or reduces the need for sensors to detect tilt of the information recording medium 2 or movement of the objective lens 28, and increases the range over which track following can be carried out by moving the objective lens 28 without moving the entire optical system.

The synchronous detector 81 and correction circuit 89 are not restricted to the configurations shown in FIG. 11. For example, the low-pass filter 82 in FIG. 11 can be replaced by a bandpass filter 94 Identical to the bandpass filter 80, as shown in FIG. 13. The preceding analysis of the signal S is unchanged by this replacement.

Other modifications that will be obvious to those skilled in the art can be made in the apparatus shown in FIGS. 1, 3, 7, 9, 10, and 11 without departing from the spirit and scope of the present invention as set forth in the following claims. 

What is claimed is:
 1. An optical apparatus for recording and reproducing information on or from an information recording medium having tracks that wobble with a certain repeating period, said apparatus comprising:a laser for emitting a laser beam; an optical system for receiving said laser beam and forming a spot on said information recording medium; a split photodetector for receiving reflected light from said spot and generating a pair of electrical signals; a differential amplifier coupled to receive said pair of electrical signals and generate a difference signal; a summing amplifier coupled to receive said pair of electrical signals and generate a sum signal; a filter coupled to receive said difference signal and extract a wobble component thereof; a synchronous detector coupled to receive and synchronously detect said sum signal and said wobble component, thereby generating a correction signal; and a correction circuit coupled to receive and combine said difference signal and said correction signal, thereby generating a tracking error signal.
 2. The apparatus of claim 1, wherein said filter is a bandpass filter.
 3. The apparatus of claim 1, wherein said synchronous detector comprises a low-pass filter for filtering said sum signal.
 4. The apparatus of claim 1, wherein said synchronous detector comprises a bandpass filter for filtering said sum signal.
 5. The apparatus of claim 1, wherein said synchronous detector comprises a multiplier.
 6. The apparatus of claim 1, wherein said synchronous detector comprises a low-pass filter for rejecting a wobble frequency component of said correction signal.
 7. The apparatus of claim 1, wherein said correction circuit comprises an amplifier for amplifying said correction signal to generate an amplified correction signal, and a differential amplifier for subtracting said amplified correction signal from said difference signal. 